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INSTITUTE OF AERONAUTICAL ENGINEERING
(Autonomous)
Dundigal, Hyderabad -500 043
LINEAR AND DIGITAL
IC APPLICATIONS
Prepared by 1. Mr. D Kalandar Basha, Associate Professor 2. Mr. B Naresh, Assistant Professor 3. Mr. N NAGARAJU, Assistant professor
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Course Contents
Unit 1
Unit 2
- Operational Amplifier
- OP-Amp,IC555 & IC565 Applications
Unit 3 - Data Converters
Unit 4 - Digital Integrated circuits
- Sequential Logic IC’s & Memories Unit 5
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Text Books:
1. Linear Integrated Circuits – D. Roy Choudhury
2. Op-Amps & Linear ICs – Ramakanth A. Gayakwad.
3. Digital Fundamentals – Floyd and Jain
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Unit 1- Integrated Circuits
What is an Integrated Circuit?
Where do you use an Integrated Circuit?
Why do you prefer an Integrated Circuit to the circuits
made by interconnecting discrete components?
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Def: The “Integrated Circuit “ or IC is a miniature,
low cost electronic circuit consisting of active and
passive components that are irreparably joined
together on a single crystal chip of silicon.
In 1958 Jack Kilby of Texas Instruments invented first IC
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Applications of an Integrated Circuit
Communication
Control
Instrumentation
Computer
Electronics
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Small size
Low cost
Less weight
Low supply voltages
Low power consumption
Highly reliable
Matched devices
Fast speed
Advantages:
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Classification
Digital ICs Linear ICs
Integrated circuits
Pn junction
isolation
Hybrid circuits
Dielectric
isolation
Monolithic circuits
Bipolar Uni polar
MOSFET JFET
Classification of ICs
Thick
&Thin film
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Chip size and Complexity
ULSI (more than one million active devices are integrated on single
chip)
Invention of Transistor (Ge) - 1947
Development of Silicon - 1955-1959
Silicon Planar Technology - 1959
First ICs, SSI (3- 30gates/chip) - 1960
MSI ( 30-300 gates/chip) - 1965-1970
LSI ( 300-3000 gates/chip) -1970-1975
VLSI (More than 3k gates/chip) - 1975
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SSI MSI LSI VLSI ULSI
< 100 active 100-1000 1000- >100000 Over 1
devices active 100000 active million
devices active devices active
devices devices
Integrated
resistors,
diodes &
BJT’s
BJT’s and
Enhanced
MOSFETS
MOSFETS 8bit, 16bit
Microproces
sors
Pentium
Microproces
sors
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Selection of IC Package
Type Criteria
Metal can
package
1. Heat dissipation is important
2. For high power applications like power
amplifiers, voltage regulators etc.
DIP 1. For experimental or bread boarding
purposes as easy to mount
2. If bending or soldering of the leads is
not required
3. Suitable for printed circuit boards as
lead spacing is more
Flat pack 1. More reliability is required
2. Light in weight
3. Suited for airborne applications
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Factors affecting selection of IC package
Relative cost
Reliability
Weight of the package
Ease of fabrication
Power to be dissipated
Need of external heat sink
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1. Military temperature range : -55o C to +125o C (-55o C to +85o C)
2. Industrial temperature range : -20o C to +85o C (-40o C to +85o C )
3. Commercial temperature range: 0o C to +70o C (0o C to +75o C )
Temperature Ranges
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The operational amplifier (Op-Amp) is a multi-
terminal device which internally is quite
complex.
Operational Amplifier
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Operational Amplifier
An “Operational amplifier” is a direct coupled high-gain
amplifier usually consisting of one or more differential
amplifiers and usually followed by a level translator and
output stage.
The operational amplifier is a versatile device that can be
used to amplify dc as well as ac input signals and was
originally designed for computing such mathematical
functions as addition, subtraction, multiplication and
integration.
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Basic Information of Op-Amp
Op-amps have five basic terminals, that is, two input
terminals, one output terminal and two power supply
terminals.
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The metal can (TO)
Package
The Dual-in-Line (DIP)
Package
The Flat Package
Packages
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Basic Information of an Op-amp
contd…
Power supply connection:
The power supply voltage may range from about + 5V to
+ 22V.
The common terminal of the V+ and V- sources is
connected to a reference point or ground.
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Manufacturer’s Designation for Linear ICs
Fairchild
National Semiconductor
Motorola
RCA
Texas Instruments
Signetics
Burr- Brown
- µA, µAF
- LM,LH,LF,TBA
- MC,MFC
- CA,CD
- SN
- N/S,NE/SE
- BB
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Fairchild’s original µA741 is also manufactured by
other manufactures as follows
National Semiconductor - LM741
Motorola - MC1741
RCA - CA3741
Texas Instruments - SN52741
Signetics - N5741
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741 Military grade op-amp
741C Commercial grade op-amp
741A Improved version of 741
741E
741S
Improved version of 741C
Military grade op-amp with higher slew rate
741SC Commercial grade op-amp with higher slew rate
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Differential Amplifier
V0 =Ad (V1 – V2 )
Ad =20 log10 (Ad ) in dB
Vc =
CMRR= ρ = | |A
2
(V1 V2 )
d
Ac
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Characteristics and performance parameters of
Op-amp
Input offset Voltage
Input offset current
Input bias current
Differential input resistance
Input capacitance
Open loop voltage gain
CMRR
Output voltage swing
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Characteristics and performance parameters of Op-
amp
Output resistance
Offset adjustment range
Input Voltage range
Power supply rejection ratio
Power consumption
Slew rate
Gain – Bandwidth product
Equivalent input noise voltage and current
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Characteristics and performance parameters of Op-
amp
Average temperature coefficient of offset parameters
Output offset voltage
Supply current
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1. Input Offset Voltage
The differential voltage that must be applied between the
two input terminals of an op-amp, to make the output
voltage zero.
It is denoted as Vios
For op-amp 741C the input offset voltage is 6mV
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2. Input offset current
The algebraic difference between the currents flowing into
the two input terminals of the op-amp
It is denoted as Iios = | Ib1 – Ib2|
For op-amp 741C the input offset current is 200nA
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3. Input bias current
The average value of the two currents flowing
into the op-amp input terminals
It is expressed mathematically as
I b 1 I b 2
2
For 741C the maximum value of Ib is 500nA
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4. Differential Input Resistance
It is the equivalent resistance measured at either the
inverting or non-inverting input terminal with the other
input terminal grounded
It is denoted as Ri
For 741C it is of the order of 2MΩ
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5. Input capacitance
It is the equivalent capacitance measured at either the
inverting or non- inverting input terminal with the other
input terminal grounded.
It is denoted as Ci
For 741C it is of the 1-4 pF
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6. Open loop Voltage gain
It is the ratio of output voltage to the differential input
voltage, when op-amp is in open loop configuration,
without any feedback. It is also called as large signal
voltage gain
It is denoted as AOL AOL=Vo / Vd
For 741C it is typically 200,000
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7. CMRR
It is the ratio of differential voltage gain Ad to common mode
voltage gain Ac
CMRR = Ad / Ac
Ad is open loop voltage gain AOL and Ac = VOC / Vc
For op-amp 741C CMRR is 90 dB
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8. Output Voltage swing
The op-amp output voltage gets saturated at +Vcc and –
VEE and it cannot produce output voltage more than +Vcc
and –VEE. Practically voltages +Vsat and –Vsat are
slightly less than +Vcc and –VEE .
For op-amp 741C the saturation voltages are + 13V for supply voltages + 15V
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9. Output Resistance
It is the equivalent resistance measured between the output
terminal of the op-amp and ground
It is denoted as Ro
For op-amp 741 it is 75Ω
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10. Offset voltage adjustment range
The range for which input offset voltage can be adjusted
using the potentiometer so as to reduce output to zero
For op-amp 741C it is + 15mV
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11. Input Voltage range
It is the range of common mode voltages which can be
applied for which op-amp functions properly and given
offset specifications apply for the op-amp
For + 15V supply voltages, the input voltage range is + 13V
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12. Power supply rejection ratio
PSRR is defined as the ratio of the change in input offset
voltage due to the change in supply voltage producing it,
keeping the other power supply voltage constant. It is
also called as power supply sensitivity (PSV)
PSRR= (Δvios / ΔVcc)|constant VEE PSRR= (Δvios / ΔVEE)|constant Vcc
The typical value of PSRR for op-amp 741C is 30µV/V
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13. Power Consumption
It is the amount of quiescent power to be consumed by op-
amp with zero input voltage, for its proper functioning
It is denoted as Pc
For 741C it is 85mW
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14. Slew rate
It is defined as the maximum rate of change of output
voltage with time. The slew rate is specified in V/µsec
Slew rate = S = dVo / dt |max
It is specified by the op-amp in unity gain condition.
The slew rate is caused due to limited charging rate of the
compensation capacitor and current limiting and saturation of the
internal stages of op-amp, when a high frequency large amplitude
signal is applied.
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Slew rate
It is given by dVc /dt = I/C
For large charging rate, the capacitor should be small or
the current should be large.
S = Imax / C
For 741 IC the charging current is 15 µA and
the internal capacitor is 30 pF. S= 0.5V/ µsec
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Slew rate equation
Vs = Vm sinωt
Vo = Vm sinωt
S =slew rate =
dt
dVo = V ω cosωt m
dt
dVo
max
S = Vm ω = 2 π f Vm
S = 2 π f Vm V / sec
For distortion free output, the
maximum allowable input
frequency fm can be obtained as
m
m
S
2 V f
This is also called full
power bandwidth of the
op-amp
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15. Gain – Bandwidth product
It is the bandwidth of op-amp when voltage gain is unity (1).
It is denoted as GB.
The GB is also called unity gain bandwidth
(UGB) or closed loop bandwidth
It is about 1MHz for op-amp 741C
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16. Equivalent Input Noise Voltage and Current
The noise is expressed as a power density
Thus equivalent noise voltage is expressed as V2 /Hz
while the equivalent noise current is expressed as A2
/Hz
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17. Average temperature coefficient of offset parameters
The average rate of change of input offset voltage per unit
change in temperature is called average temperature coefficient of
input offset voltage or input offset voltage drift
It is measured in µV/oC. For 741 C it is 0.5 µV/oC
The average rate of change of input offset current per unit
change in temperature is called average temperature coefficient of
input offset current or input offset current drift
It is measured in nA/oC or pA/oC . For 741 C it is 12 pA/oC
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18. Output offset voltage ( Voos )
The output offset voltage is the dc voltage present at the
output terminals when both the input terminals are
grounded.
It is denoted as Voos
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Factors affecting parameters of Op-amp
Supply
Voltage
Frequency Temperature
1. Voltage gain
2. Output Voltage
swing
3. Input voltage range
4. Power consumption
5. Input offset current
1. Voltage gain
2. Input resistance
3. Output resistance
4. CMRR
5. Input noise voltage
6. Input noise current
1. Input offset current
2. Input offset voltage
3. Input bias current
4. Power consumption
5. Gain-Bandwidth
product
6. Slew rate
7. Input resistance
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Parameter consideration for various
applications
For A.C. applications For D.C. applications
Input resistance Input resistance
Output resistance Output resistance
Open loop voltage gain Open loop voltage gain
Slew rate Input offset voltage
Output voltage swing Input offset current
Gain- bandwidth product Input offset voltage and current
drifts
Input noise voltage and current
Input offset voltage and current
drifts
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Absolute Maximum Ratings of Op-amp
Maximum power dissipation: This is the maximum
power which can be dissipated, in the internal stages of
the op-amp in the form of heat
Operating temperature range: As specified in the data
sheet, op-amp can work satisfactorily, over the operating
temperature range, as required for the given application
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Maximum supply voltage: This is the maximum d.c.
supply voltage which can be applied to the op-amp
Maximum differential input voltage: This rating gives
the maximum value of difference between the two input
voltages, applied to the two input terminals of the op-
amp
Absolute Maximum Ratings of Op-amp
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Maximum common mode input voltage: This is the
maximum value of the input voltage which can be
simultaneously applied to the two input terminals
Storage temperature range: This gives the temperature
range over which the op-amp can be stored safely.
Absolute Maximum Ratings of Op-amp
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Op-amp characteristics dependent on the
power supply voltages
Absolute maximum power supply voltage
Absolute maximum differential input voltages
Absolute maximum common mode input voltage
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Ideal Op-amp
1. An ideal op-amp draws no
current at both the input terminals
I.e. I1 = I2 = 0. Thus its input
impedance is infinite. Any source
can drive it and there is no loading
on the driver stage 2. The gain of an ideal op-amp is infinite, hence the
differential input Vd = V1 – V2 is essentially zero for the
finite output voltage Vo
3. The output voltage Vo is independent of the current
drawn from the output terminals. Thus its output
impedance is zero and hence output can drive an infinite
number of other circuits
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The Ideal Operational Amplifier
Open loop voltage gain AOL
Ri
Ro
BW
= ∞
= ∞ Input Impedance
Output Impedance = 0
= ∞ Bandwidth
Zero offset (Vo = 0 when V1 = V2 = 0) Vios = 0
CMRR ρ = ∞
Slew rate S = ∞
No effect of temperature
Power supply rejection ratio PSRR = 0
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Ideal Voltage transfer curve
+Vsat
AOL = ∞
+Vsat ≈ +Vcc
-Vsat
0 +Vd -Vd
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Practical voltage transfer curve
1. If Vd is greater than corresponding to b, the output
attains +Vsat
2. If Vd is less than corresponding to a, the output attains
–Vsat
3. Thus range a-b is input range for which output varies
linearily with the input. But AOL is very high,
practically
this range is very small
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Equivalent circuit of practical op-amp
AOL = Large signal open loop voltage gain
Vd = Difference voltage V1 – V2
V1 = Non-inverting input voltage with respect to ground
V2 = Inverting input voltage with respect to ground
Ri = Input resistance of op-amp
Ro = Output resistance of op-amp
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Transient Response Rise time
When the output of the op-amp is suddenly changing like
pulse type, then the rise time of the response depends on
the cut-off frequency fH of the op-amp. Such a rise time is
called cut-off frequency limited rise time or transient
response rise time ( tr )
H
t r f
0 .3 5
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Op-amp Characteristics
DC Characteristics
Input bias current Input offset current Input
offset voltage Thermal drift
AC Characteristics
Slew rate Frequency response
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DC Characteristics Thermal Drift
The op-amp parameters input offset
voltage Vios and input offset current
Iios are not constants but vary with
the factors
1. Temperature
2. Supply Voltage changes
3. Time
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Thermal Voltage Drift
It is defined as the average rate of change of input offset voltage per
unit change in temperature. It is also called as input offset
voltage drift
Input offset voltage drift =
T
∆Vios = change in input offset voltage
∆T = Change in temperature
V io s
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It is expressed in μV/0 c. The drift is not constant and it is
not uniform over specified operating temperature range.
The value of input offset voltage may increase or
decrease with the increasing temperature
2
1
0
-1
-2 TA , ambient
temp in oc
-25 0 25 50 75 -55
Slope can be of
either polarities Vios
in
mv
Input Offset Voltage Drift
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Input bias current drift
It is defined as the average rate of change of input bias
current per unit change in temperature
Thermal drift in input bias current =
T
It is measured in nA/oC or pA/oc. These parameters vary
randomly with temperature. i.e. they may be positive
in one temperature range and negative in another
Ib
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Input bias current drift
100
80
60
40
20
-55 -25 0 25 50 75
TA ambient temp.
in oC
Ib in
nA
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Input Offset current drift
It is defined as the average rate of change of input offset
current per unit change in temperature
Thermal drift in input offset current =
T
I ios
It is measured in nA/oC or pA/oc. These parameters vary randomly with
temperature. i.e. they may be positive in one temperature range and negative in
another
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2
1
0
-1
-2 TA , ambient
temp in oc
-25 0 25 50 75 -55
Slope can be of
either polarities Iios
nA in
Input Offset current Drift
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AC Characteristics
Frequency Response
Ideally, an op-amp should have an infinite bandwidth but practically op-
amp gain decreases at higher frequencies. Such a gain reduction
with respect to frequency is called as roll off.
The plot showing the variations in magnitude and phase
angle of the gain due to the change in frequency is called
frequency response of the op-amp
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When the gain in decibels, phase angle in degrees are
plotted against logarithmic scale of frequency, the plot is
called Bode Plot
The manner in which the gain of the op-amp changes with
variation in frequency is known as the magnitude plot.
The manner in which the phase shift changes with variation
in frequency is known as the phase-angle plot.
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Obtaining the frequency response
To obtain the frequency response , consider the high frequency model
of the op-amp with capacitor C at the output, taking into account the
capacitive effect present
1 j2fRoC
AOL A ( f ) OL
f
) f o
1 j(
A ( f ) AOL
OL
Where
AOL(f) = open loop voltage gain as a
function of frequency
AOL = Gain of the op-amp at 0Hz F =
operating frequency
Fo = Break frequency or cutoff
frequency of op-amp
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2
1
A ( f )
fo
f
AOL
OL
f0
f A ( f ) ( f ) tan1
OL
For a given op-amp and selected value of C, the frequency fo is constant.
The above equation can be written in the polar form as
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Frequency Response of an op-amp
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The following observations can be made from the frequency response of an
op-amp
i) The open loop gain AOL is almost constant from 0 Hz to the break
frequency fo .
ii) At f=fo , the gain is 3dB down from its value at 0Hz . Hence the frequency
fo is also called as -3dB frequency. It is also know as corner frequency
After f=fo , the gain AOL (f) decreases at a rate of 20 dB/decade or
6dB/octave. As the gain decreases, slope of the magnitude plot is -
20dB/decade or -6dB/octave, after f=fo .
iv) At a certain frequency, the gain
reduces to 0dB. This means 20log|AOL | is
0dB i.e. |AOL | =1. Such a frequency is called gain cross-over frequency or
unity gain bandwidth (UGB). It is also called closed loop bandwidth.
iii)
UGB is the gain bandwidth product only if an op-amp has a single breakover
frequency, before AOL (f) dB is zero.
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For an op-amp with single break frequency fo , after fo
the gain bandwidth product is constant equal to UGB
UGB=AOL fo
UGB is also called gain bandwidth product and denoted as ft Thus
ft is the product of gain of op-amp and bandwidth.
The break frequency is nothing but a corner frequency fo . At this
frequency, slope of the magnitude plot changes. The op-amp for
which there is only once change in the slope of the magnitude plot,
is called single break frequency op-amp.
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For a single break frequency we can also write
UGB= Af ff
Af = closed loop voltage gain Ff =
bandwidth with feedback
v) The phase angle of an op-amp with
single break frequency varies between 00 to 900 . The maximum possible
phase shift is -900 , i.e. output voltage lags input voltage by 900 when
phase shift is maximum
vi) At a corner frequency f=fo , the phase
shift is -450. F o = UGB / AOL
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The modes of using an op-amp
Open Loop : (The output assumes one of the two
possible output states, that is +Vsat or – Vsat and the
amplifier acts as a switch only).
Closed Loop: ( The utility of an op-amp can be greatly
increased by providing negative feed back. The output in
this case is not driven into saturation and the circuit
behaves in a linear manner).
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Open loop configuration of op-amp
The voltage transfer curve indicates the inability of op-
amp to work as a linear small signal amplifier in the open
loop mode
Such an open loop behaviour of the op-amp finds some
rare applications like voltage comparator, zero crossing
detector etc.
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Open loop op-amp configurations
The configuration in which output depends on input, but output has
no effect on the input is called open loop configuration.
No feed back from output to input is used in such configuration.
The opamp works as high gain amplifier
The op-amp can be used in three modes in open loop
configuration they are
1. Differential amplifier
2. Inverting amplifier
3. Non inverting amplifier
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Differential Amplifier
The amplifier which amplifies the difference between the two input
voltages is called differential amplifier.
V o AOLVd AOL (V1 V2 ) AOL (Vin1 Vin2 )
Key point: For very small Vd , output gets driven into saturation due to high AOL ,
hence this application is applicable for very small range of differential input
voltage.
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Inverting Amplifier
The amplifier in which the output is inverted i.e. having 180o
phase shift with respect to the input is called an inverting
amplifier
Vo = -AOL Vin2
Keypoint: The negative sign indicates that there is phase shift of 180o between
input and output i.e. output is inverted with respect to input.
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Non-inverting Amplifier
The amplifier in which the output is amplified without any
phase shift in between input and output is called non
inverting amplifier
Vo = AOL Vin1
Keypoint: The positive output shows that input and output are in phase and
input is amplified AOL times to get the output.
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Why op-amp is generally not used in open loop
mode?
As open loop gain of op-amp is very large, very small input
voltage drives the op-amp voltage to the saturation level.
Thus in open loop configuration, the output is at its
positive saturation voltage (+Vsat ) or negative saturation
voltage (-Vsat ) depending on which input V1 or V2 is more
than the other. For a.c. input voltages, output may
switch between positive and negative saturation voltages
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This indicates the inability of op-amp to work as a linear small signal
amplifier in the open loop mode. Hence the op-amp in open loop
configuration is not used for the linear applications
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General purpose op-amp 741
The IC 741 is high performance monolithic op-amp IC. It is
available in 8pin, 10pin or 14pin configuration. It can
operate over a temperature of -550 C to 1250 C.
Features:
i) No frequency compensation required
ii) Short circuit protection provided
iii) Offset Voltage null capability
iv) Large common mode and differential voltage range
v) No latch up
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Internal schematic of 741 op-amp
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The 8pin DIP package of IC 741
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Realistic simplifying assumptions
Zero input current: The current drawn by either of the
input terminals (inverting and non-inverting) is zero
Virtual ground :This means the differential input voltage
Vd between the non-inverting and inverting terminals is
essentially zero. (The voltage at the non inverting input
terminal of an op-amp can be realistically assumed to be
equal to the voltage at the inverting input terminal
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Closed loop operation of op-amp
The utility of the op-amp can be increased considerably by
operating in closed loop mode. The closed loop
operation is possible with the help of feedback. The
feedback allows to feed some part of the output back to
the input terminals. In the linear applications, the op-
amp is always used with negative feedback. The
negative feedback helps in controlling gain, which
otherwise drives the op-amp out of its linear range, even
for a small noise voltage at the input terminals
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Ideal Inverting Amplifier
1. The output is inverted with respect to input, which is indicated by minus
sign.
2. The voltage gain is independent of open loop gain of the op-amp, which is
assumed to be large.
3. The voltage gain depends on the ratio of the two resistances.
Hence selecting Rf and R1 , the required value of gain can be easily
obtained.
4. If Rf > R1,, the gain is greater than 1 If Rf < R1,, the gain is less than 1
If Rf = R1, the gain is unity
Thus the output voltage can be greater than, less than or equal to the input
voltage in magnitude
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5. If the ratio of Rf and R1 is K which is other than one, the circuit is called
scale changer while for Rf/R1 =1 it is called phase inverter.
The closed loop gain is denoted as AVF or ACL i.e. gain with feedback 6.
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Ideal Non-inverting Amplifier
1. The voltage gain is always greater than one
2. The voltage gain is positive indicating that for a.c. input, the output
and input are in phase while for d.c. input, the output polarity is
same as that of input
3. The voltage gain is independent of open loop gain of op-amp, but
depends only on the two resistance values
4. The desired voltage gain can be obtained by selecting proper
values of Rf and R1
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Comparison of the ideal inverting and non-
inverting op-amp
Ideal Inverting amplifier Ideal non-inverting amplifier
1. Voltage gain=-Rf/R1 1. Voltage gain=1+Rf/R1
2. The output is inverted with
respect to input
2. No phase shift between input
and output
3. The voltage gain can be
adjusted as greater than, equal to
or less than one
3. The voltage gain is always
greater than one
4. The input impedance is R1 4. The input impedance is very
large
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Practical Inverting Amplifier
1 OL f
AOL R f
CL R R R A
A 1
Closed Loop Voltage gain =
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Practical Non-Inverting Amplifier
Closed Loop Voltage gain = ACL
A (R R ) OL 1 f
R1 R f R1 AOL
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Instrumentation Amplifier
In a number of industrial and consumer
applications, the measurement of physical quantities
is usually done with the help of transducers. The output
of transducer has to be amplified So that it can
drive the indicator or display system. This function is
performed by an instrumentation amplifier
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Instrumentation Amplifier
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Features of instrumentation amplifier
1. high gain accuracy
2. high CMRR
3. high gain stability with low temperature co-
efficient
4. low dc offset
5. low output impedance
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AC AMPLIFIER
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Differentiator
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Integrator
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Differential amplifier
This circuit amplifies only the difference between
the two inputs. In this circuit there are two
resistors labeled R IN Which means that their
values are equal. The differential amplifier
amplifies the difference of two inputs while the
differentiator amplifies the slope of an input
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Summer
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Comparator
A comparator is a circuit which compares
a signal voltage applied at one input of an
op- amp with a known reference voltage at
the other input. It is an open loop op - amp
with output + Vsat
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Comparator
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Applications of comparator
1. Zero crossing detector
2. Window detector
3. Time marker generator
4. Phase detector
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Schmitt trigger
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INTRODUCTION TO VOLTAGE
REGULATORS
A voltage regulator is designed to
automatically maintain a constant voltage
level. A voltage regulator may be a
simple "feed-forward" design or may
include negative feedback control loops. It
may use an electromechanical
mechanism, or electronic components.
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IC Voltage Regulators
There are basically two kinds of IC voltage regulators:
Multipin type, e.g. LM723C
3-pin type, e.g. 78/79XX
Multipin regulators are less popular but they provide the
greatest flexibility and produce the highest quality
voltage regulation
3-pin types make regulator circuit design simple
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Multipin IC Voltage Regulator
The LM723 has an
equivalent circuit that
contains most of the parts
of the op-amp voltage
regulator discussed
earlier.
It has an internal voltage
reference, error amplifier,
pass transistor, and
current limiter all in one
IC package.
LM 723C Schematic
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LM723 Voltage Regulator
Can be either 14-pin DIP or 10-pin TO-100 can
May be used for either +ve or -ve, variable or fixed
regulated voltage output
Using the internal reference (7.15 V), it can operate as a
high-voltage regulator with output from 7.15 V to about
37 V, or as a low-voltage regulator from 2 V to 7.15 V
Max. output current with heat sink is 150 mA
Dropout voltage is 3 V (i.e. VCC > Vo(max) + 3)
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LM723 in High-Voltage Configuration
External pass transistor and
current sensing added.
Design equations:
R2
V (R R )
V ref 1 2
o
1 2
R1R2 3
R R R
max
0.7 Rsens I
Choose R1 + R2 = 10
k,
and Cc = 100 pF.
To make Vo variable,
replace R1 with a pot.
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LM723 in Low-Voltage Configuration
With external pass transistor
and foldback current limiting
5 sens
R
4 V
o 0.7(R
4 R
5 )
L(max)
R R I
5 sens
0.7(R
4 R
5 )
sho rt
R R I
short o L(max)
o
sens
I (V 0.7) 0.7I
0.7V R
5 sens 4 L
V ' 0.7R
L (R
4 R
5 )
o
R R R R
Under foldback condition:
2 1
2 r ef
o
R R
R V V
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Three-Terminal Fixed Voltage Regulators
Less flexible, but simple to use
Come in standard TO-3 (20 W) or TO-220 (15 W)
transistor packages
78/79XX series regulators are commonly available with
5, 6, 8, 12, 15, 18, or 24 V output
Max. output current with heat sink is 1 A
Built-in thermal shutdown protection
3-V dropout voltage; max. input of 37 V
Regulators with lower dropout, higher in/output, and
better regulation are available.
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Both the 78XX and 79XX regulators can be used to
provide +ve or -ve output voltages
C1 and C2 are generally optional. C1 is used to cancel
any inductance present, and C2 improves the transient
response. If used, they should preferably be either 1 F
tantalum type or 0.1 F mica type capacitors.
Basic Circuits With 78/79XX Regulators
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Dual-Polarity Output with 78/79XX
Regulators
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78XX Regulator with Pass Transistor
Q1 starts to conduct when
VR2 = 0.7 V.
R2 is typically chosen so
that max. IR2 is 0.1 A.
Power dissipation of Q1 is
P = (Vi - Vo)IL.
Q2 is for current limiting
protection. It conducts
when VR1 = 0.7 V.
Q2 must be able to pass
max. 1 A; but note that max. VCE2 is only 1.4 V.
Imax 1
R 0.7
IR 2 2
0.7
R
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78XX Floating Regulator
It is used to obtain an
output > the Vreg
value up to a max.of
37 V.
R1 is chosen so that
R1 0.1 Vreg/IQ,
where I is the
IQ R2
R1
V reg Vreg Vo
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3-Terminal Variable Regulator
The floating regulator could be made into a variable
regulator by replacing R2 with a pot. However, there are
several disadvantages:
Minimum output voltage is Vreg instead of 0 V.
IQ is relatively large and varies from chip to chip.
Power dissipation in R2 can in some cases be quite
large resulting in bulky and expensive equipment.
A variety of 3-terminal variable regulators are available,
e.g. LM317 (for +ve output) or LM 337 (for -ve output).
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Basic LM317 Variable Regulator Circuits
(a)
Circuit with capacitors
to improve performance
(b)
Circuit with protective
diodes
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Notes on Basic LM317 Circuits
The function of C1 and C2 is similar to those used in
the 78/79XX fixed regulators.
C3 is used to improve ripple rejection.
Protective diodes in circuit (b) are required for high-
current/high-voltage applications.
Iadj R2
R1
V ref Vref Vo
where Vref = 1.25 V, and Iadj is
the current flowing into the adj.
terminal (typically 50 A).
R1 = Vref /IL(min), where IL(min) is typically 10 mA. Vref IadjR1
R (V V )
1 o ref
2 R
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LM317 Regulator Circuits
Circuit with pass transistor
and current limiting
Circuit to give 0V min.
output voltage
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UNIT –II
Opamp -555
IC-565 applications
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Filter
Filter is a frequency selective circuit that passes
signal of specified Band of frequencies and
attenuates the signals of frequencies outside the band
Type of Filter
1. Passive filters
2. Active filters
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Passive filters Passive filters works well for high frequencies.
But at audio frequencies, the
problematic, as they become
inductors become
large, heavy and
expensive.For low frequency applications, more number
of turns of wire must be used which in turn adds to
the series resistance degrading inductor’s
performance ie, low Q, resulting in high power
dissipation
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Active filters
elements. By enclosing a capacitor in the feed back loop
, inductor less active filters can be obtained
Active filters used op- amp as the active
element and resistors and capacitors as passive
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some commonly used active filters
1. Low pass filter
2. High pass filter
3. Band pass filter
4. Band reject filter
5. All pass filter
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Active Filters
Active filters use op-amp(s) and RC components.
Advantages over passive filters:
op-amp(s) provide gain and overcome circuit losses
increase input impedance to minimize circuit loading
higher output power
sharp cutoff characteristics can be produced simply
and efficiently without bulky inductors
Single-chip universal filters (e.g. switched-capacitor
ones) are available that can be configured for any type of
filter or response.
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Review of Filter Types & Responses
4 major types of filters: low-pass, high-pass, band pass,
and band-reject or band-stop
0 dB attenuation in the passband (usually)
3 dB attenuation at the critical or cutoff frequency, fc (for
Butterworth filter)
Roll-off at 20 dB/dec (or 6 dB/oct) per pole outside
the passband (# of poles = # of reactive elements).
Attenuation at any frequency, f, is:
x atten.(dB) at fdec
fc
f atten.(dB) at f log
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Review of Filters (cont’d)
Bandwidth of a filter: BW = fcu - fcl
Phase shift: 45o/pole at fc; 90o/pole at >> fc
4 types of filter responses are commonly used:
Butterworth - maximally flat in passband; highly non-
linear phase response with frequecny
Bessel - gentle roll-off; linear phase shift with freq.
Chebyshev - steep initial roll-off with ripples in
passband
Cauer (or elliptic) - steepest roll-off of the four types
but has ripples in the passband and in the stopband
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Frequency Response of Filters
f
A(dB)
fc
f fcl fcu
f
fcl fcu f
A(dB)
BRF
A(dB) A(dB) HPF A(dB)
BPF
fc
f
LPF
Pass-
band
Butterworth
Bessel Chebyshev
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Unity-Gain Low-Pass Filter Circuits
2-pole 3-pole
4-pole
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Design Procedure for Unity-Gain LPF
Determine/select number of poles required.
Calculate the frequency scaling constant, Kf = 2f
Divide normalized C values (from table) by Kf to obtain
frequency-scaled C values.
Select a desired value for one of the frequency-scaled C
values and calculate the impedance scaling factor:
frequency scaled C value
desired C value K x
Divide all frequency-scaled C values by Kx
Set R = Kx
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An Example
Design a unity-gain LP Butterworth filter with a critical
frequency of 5 kHz and an attenuation of at least 38 dB
at 15 kHz.
The attenuation at 15 kHz is 38 dB
the attenuation at 1 decade (50 kHz) = 79.64 dB.
We require a filter with a roll-off of at least 4 poles.
Kf = 31,416 rad/s. Let’s pick C1 = 0.01 F (or 10
nF). Then C2 = 8.54 nF, C3 = 24.15 nF, and C4 = 3.53 nF.
Pick standard values of 8.2 nF, 22 nF, and 3.3 nF. Kx =
3,444
Make all R = 3.6 k (standard value)
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Unity-Gain High-Pass Filter Circuits
2-pole 3-pole
4-pole
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Design Procedure for Unity-Gain HPF
The same procedure as for LP filters is used except for
step #3, the normalized C value of 1 F is divided by Kf.
Then pick a desired value for C, such as 0.001 F to 0.1
F, to calculate Kx. (Note that all capacitors have the
same value).
For step #6, multiply all normalized R values (from table)
by Kx.
E.g. Design a unity-gain Butterworth HPF with a critical
frequency of 1 kHz, and a roll-off of 55 dB/dec. (Ans.: C
= 0.01 F, R1 = 4.49 k, R2 = 11.43 k, R3 = 78.64 k.;
pick standard values of 4.3 k, 11 k, and 75 k).
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Equal-Component Filter Design
2-pole LPF
Same value R & same value C
are used in
filter.
Select C
(e.g. 0.01 F), then:
2-pole HPF
Av for # of poles is given in
a table and
is the same for
LP and HP
filter design. A
RF 1
I
v R
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Example
Design an equal-component LPF with a critical
frequency of 3 kHz and a roll-off of 20 dB/oct.
Minimum # of poles = 4
Choose C = 0.01 F; R = 5.3 k
From table, Av1 = 1.1523, and Av2 = 2.2346.
Choose RI1 = RI2 = 10 k; then RF1 = 1.5 k, and
RF2 =
12.3 k .
Select standard values: 5.1 k, 1.5 k, and 12 k.
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Bandpass and Band-Rejection Filter
fcl fctr fcl fctr fcu fcu
f f
Att
enuat
ion
(dB
)
Att
enuat
ion
(dB
) The quality factor, Q, of a filter is given by:
where BW = fcu - fcl and Q
fctr
BW
fctr fcu fcl
BPF BRF
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More On Bandpass Filter
If BW and fcentre are given, then:
4 2 4 2 ; fcu f 2
BW 2
f 2 BW 2
BW BW f ctr ctr cl
A broadband BPF can be obtained by combining a LPF and
a HPF:
The Q of this filter is usually
> 1.
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Broadband Band-Reject Filter
A LPF and a HPF can also be combined to give a broadband
BRF:
2-pole band-reject filter
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Narrow-band Bandpass Filter
Q
2 R1
C
BW fctr 1
2Q2 1
R1 3 R
C1 = C2 = C
R2 = 2 R1
R3
1 R1
2
2 R1
C
1 f ctr
R3 can be adjusted or trimmed
to change f without affecting ctr
the BW. Note that Q < 1.
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Narrow-band Band-Reject Filter
Easily obtained by combining the inverting output of a
narrow-band BRF and the original signal:
The equations for R1, R2, R3, C1, and C2 are the same as before.
RI = RF for unity gain and is often chosen to be >> R1.
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TRIANGULAR WAVE
GENERATOR
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555 IC
The 555 timer is
specifically designed
an integrated
to perform
circuit
signal
generation and timing functions.
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Features of 555 Timer Basic blocks
1.. It has two basic operating modes: monostable
and astable
2. It is available in three packages. 8 pin metal can ,
8 pin dip, 14 pin dip.
3. It has very high temperature stability
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Applications of 555 Timer
1. astable multivibrator . 2. monostable multivibrator
3. Missing pulse detector
4. Linear ramp generator
5. Frequency divider
6. Pulse width modulation
7. FSK generator
8. Pulse position modulator
9. Schmitt trigger
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Astable multivibrator
.
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Astable multivibrator
. When the voltage on the capacitor reaches (2/3)Vcc, a switch is closed at pin 7 and the capacitor is discharged to (1/3)Vcc, at which time the switch is opened and the cycle starts over
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Monostable multivibrator
.
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Voltage controlled oscillator
A voltage controlled oscillator is an
oscillator circuit in which the frequency of
oscillations can be controlled by an externally
applied voltage
The features of 566 VCO
1. Wide supply voltage range(10- 24V)
2. Very linear modulation characteristics
3. High temperature stability
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UNIT - III
DATA
CONVERTETRS
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Classification of ADCs
1. Direct type ADC.
2. Integrating type ADC
Direct type ADCs
1. Flash (comparator) type converter
2. Counter type converter
3. Tracking or servo converter.
4. Successive approximation type converter
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Integrating type converters
An ADC converter that perform conversion
in an indirect manner by first changing the
analog I/P signal to a linear function of time or
frequency and then to a digital code is
known as integrating type A/D converter
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Digital Logic families
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Overview
• Integration, Moore’s law
• Early families (DL, RTL)
• TTL
• Evolution of TTL family
• ECL
• CMOS family and its evolution
• Overview
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Integration Levels
• Gate/transistor ratio is roughly 1/10
– SSI
– MSI
– LSI
– VLSI
– ULSI
– GSI
< 12 gates/chip
< 100 gates/chip
…1K gates/chip
…10K gates/chip
…100K gates/chip
…1Meg gates/chip
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Moore’s law
• A prediction made by Moore (a co-founder of Intel) in
1965: “… a number of transistors to double every 2
years.”
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In the beginning…
=
Diode Logic (DL)
•simplest; does not
scale
•NOT not possible
(need an active
eRleesmisetnotr)-
Transistor Logic (RTL)
•replace diode switch
with a transistor switch
•can be cascaded
•large power draw
=
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was…
=
Diode-Transistor Logic (DTL)
•essentially diode logic with transistor
amplification
•reduced power consumption
•faster than RTL
DL AND gate Saturating inverter
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VOH(min) – The minimum voltage level at an output in the logical “1” state under
defined load conditions
VOL(max) – The maximum voltage level at an output in the logical “0” state under
defined load conditions
VIH(min) – The minimum voltage required at an input to be recognized as “1”
logical state
VIL(max) – The maximum voltage required at an input that still will be recognized
as “0” logical state
Logic families: V levels
VIH VOH VOL VIL
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IOH – Current flowing into an output in the logical “1” state under specified load
conditions
IOL – Current flowing into an output in the logical “0” state under specified load
conditions
IIH – Current flowing into an input when a specified HI level is applied to that
input IIL – Current flowing into an input when a specified LO level is applied to
that input
Logic families: I requirements
IOH
VIH VOH VOL VIL
IIH IOL IIL
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Fanout: the maximum number of logic inputs (of the
same logic family) that an output can drive reliably
Logic families: fanout
DC fanout = min( IOH IOL
I ),
I IH IL
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Logic families: propagation delay
TPD,HL TPD,LH
TPD,HL – input-to-output
propagation delay from HI
to LO output TPD,LH – input-
to-output propagation delay
from LO to HI output
Speed-power
product: TPD Pavg
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Logic families: noise margin
HI state noise margin:
VNH = VOH(min) – VIH(min)
LO state noise margin:
VNL = VIL(max) – VOL(max)
Noise margin:
VN = min(VNH,VNL) VNH
VNL
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TTL
2-input NAND
Bipolar Transistor-Transistor Logic (TTL) •first introduced by in 1964 (Texas Instruments)
•TTL has shaped digital technology in many ways
•Standard TTL family (e.g. 7400) is obsolete
•Newer TTL families still used (e.g. 74ALS00)
Distinct features
• Multi-emitter transistors
• Totem-pole transistor
arrangement
• Open LTspice example:
TTL NAND…
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TTL evolution Schottky series (74LS00) TTL
•A major slowdown factor in BJTs is due to
transistors going in/out of saturation
•Shottky diode has a lower forward bias (0.25V)
•When BC junction would become forward biased,
the Schottky diode bypasses the current
preventing the transistor from going into saturation
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TTL family evolution
Legacy: don’t use in
new designs Widely used today
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ECL
Emitter-Coupled Logic (ECL) •PROS: Fastest logic family available (~1ns)
•CONS: low noise margin and high power
dissipation
•Operated in emitter coupled geometry (recall
differential amplifier or emitter-follower),
transistors are biased and operate near their Q-
point (never near saturation!)
• Logic levels. “0”: –1.7V. “1”: –0.8V
•Such strange logic levels require extra effort
when interfacing to TTL/CMOS logic families.
•Open LTspice example: ECL inverter…
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CMOS
Complimentary MOS (CMOS)
• Other variants: NMOS, PMOS (obsolete)
• Very low static power consumption
• Scaling capabilities (large integration all MOS)
• Full swing: rail-to-rail output
• Things to watch out for:
– don’t leave inputs floating (in TTL these will
float
to HI, in CMOS you get undefined behaviour)
– susceptible to electrostatic damage (finger of
death)
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Life-cycle
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Combinational
Circuits
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Outline
Boolean Algebra
Decoder
Encoder
MUX
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History: Computer and the
Rationalist
Modern research issues in AI are formed and evolve through a combination of historical, social and cultural pressures.
The rationalist tradition had an early proponent in Plato, and was continued on through the writings of Pascal, Descates, and Liebniz
For the rationalist, the external world is reconstructed through the clear and distinct ideas of a mathematics
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History: Development of Formal
Logic
The goal of creating a formal language for
thought also appears in the work of George
Boole, another 19th century mathematician
whose work must be included in the roots of AI
The importance of Boole’s accomplishment is in
the extraordinary power and simplicity of the
system he devised: Three Operations
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Three Operations
three basic Boolean operations can be
defined arithmetically as follows.
xרy=xy
xשy=x + y − xy
¬x=1 − x
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Boolean function and logic
diagram
• Boolean algebra: Deals with binary variables and logic operations operating on those variables.
• Logic diagram: Composed of graphic symbols for logic gates. A simple circuit sketch that represents inputs and outputs of Boolean functions.
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Basic Identities of Boolean Algebra
(1)
(2)
(3)
(4)
x + 0 = x
x · 0 = 0
x + 1 = 1
x · 1 = 1
(5) x + x = x
(6) x · x = x
(7) x + x’ = x
(8) x · x’ = 0
(9) x + y = y + x
(10)xy = yx
(11) x + ( y + z ) = ( x + y ) + z
(12)x (yz) = (xy) z
(13)x ( y + z ) = xy + xz
(14) x + yz = ( x + y )( x + z)
(15) ( x + y )’ = x’ y’
(16) ( xy )’ = x’ + y’
(17) (x’)’ = x
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Gates
Refer to the hardware to implement Boolean operators.
The most basic gates are
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Boolean function and truth
table
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Outline
Boolean Algebra
Decoder
Encoder
MUX
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Decoder
Accepts a value and decodes it
Output corresponds to value of n inputs
Consists of:
Inputs (n)
Outputs (2n , numbered from 0 2n - 1)
Selectors / Enable (active high or active low)
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The truth table of 2-to-4
Decoder
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2-to-4 Decoder
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2-to-4 Decoder
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The truth table of 3-to-8
Decoder A2 A1 A0 D0 D1 D2 D3 D4 D5 D6 D7
0 0 0 1
0 0 1 1
0 1 0 1
0 1 1 1
1 0 0 1
1 0 1 1
1 1 0 1
1 1 1 1
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3-to-8 Decoder
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3-to-8 Decoder with Enable
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Decoder Expansion
Decoder expansion
Combine two or more small decoders with enable inputs to form a larger decoder
3-to-8-line decoder constructed from two 2-to- 4-
line decoders The MSB is connected to the enable inputs
if A2=0, upper is enabled; if A2=1, lower is enabled.
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Decoder Expansion
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Combining two 2-4 decoders to form
one 3-8 decoder using enable switch
The highest bit is used for the enabl
es
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How about 4-16 decoder
Use how many 3-8 decoder?
Use how many 2-4 decoder?
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Outline
Boolean Algebra
Decoder
Encoder
Mux
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Encoders
Perform the inverse operation of a
decoder
2n (or less) input lines and n output lines
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Encoders
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Encoders with OR gates
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Encoders
Perform the inverse operation of a decoder
2n (or less) input lines and n output lines
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Accepts multiple values and encodes them
Works when more than one input is active
Consists of:
Inputs (2n)
Outputs
when more than one output is active, sets output to correspond to highest input
V (indicates whether any of the inputs are active)
Selectors / Enable (active high or active low)
Priority Encoder
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D3 D2 D1 D0 A1 A0 V
0 0 0 0 x X 0
0 0 0 1 0 0 1
0 0 1 0 0 1 1
0 0 1 1 0 1 1
0 1 0 0 1 0 1
0 1 0 1 1 0 1
0 1 1 0 1 0 1
0 1 1 1 1 0 1
1 0 0 0 1 1 1
1 0 0 1 1 1 1
1 0 1 0 1 1 1
1 0 1 1 1 1 1
1 1 0 0 1 1 1
1 1 0 1 1 1 1
1 1 1 0 1 1 1
1 1 1 1 1 1 1
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Priority Encoder
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Outline
Boolean Algebra
Decoder
Encoder
Mux
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Multiplexer (MUX)
A multiplexer can use addressing bits to
select one of several input bits to be the
output.
A selector chooses a single data input and
passes it to the MUX output
It has one output selected at a time.
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Function table with enable
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4 to 1 line multiplexer
4 to 1 line
multiplexer
2n MUX to 1
n for this MUX is 2
This means 2
selection lines s0
and s1
S1 S0 F
0 0 I0
0 1 I1
1 0 I2
1 1 I3
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Multiplexer (MUX)
Consists of:
Inputs (multiple) = 2n
Output (single)
Selectors (# depends on # of inputs) = n
Enable (active high or active low)
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Multiplexers versus decoders
•A Multiplexer uses n binary select bits to choose from a
maximum of 2n unique input lines.
•Decoders have 2^n number of output lines while
multiplexers have only one output line.
•The output of the multiplexer is the data input whose index is
specified by the n bit code.
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Multiplexer Versus Decoder
I
0
S1
S
0
I3
I2
X
I1
Note that the multiplexer has an extra OR gate. A1 and A0 are the two inputs
in decoder. There are four inputs plus two selecs in multiplexer.
4-to-1 Multiplexer 2-to-4 Decoder
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Cascading multiplexers
Using three 2-1 MUX
to make one 4-1 MUX
F
S1 S0 F
0 0 I0
0 1 I1
1 0 I2
1 1 I3
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I3
F
I0
I1
I 2
I4
I 5
I 6
I7
Example: Construct an
8-to-1 multiplexer using
2-to-1 multiplexers.
2-1
MUX
S E
S2 E
S2 S1 S0 F
0 0 0 I0
0 0 1 I1
0 1 0 I2
0 1 1 I3
1 0 0 I4
1 0 1 I5
1 1 0 I6
1 1 1 I7
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Example : Construct 8-to-1 multiplexer using one 2-to-1 multiplexer and
two 4-to-1 multiplexers
S2 S1 S0 X
0 0 0 I0
0 0 1 I1
0 1 0 I2
0 1 1 I3
1 0 0 I4
1 0 1 I5
1 1 0 I6
1 1 1 I7
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Quadruple 2-to-1 Line Multiplexer
Used to supply four bits to the
output. In this case two inputs four
bits each.
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Quadruple 2-to-1 Line
Multiplexer
E
(Enable)
S
(Select)
Y
(Output)
0 X All 0’s
1 0 A
1 1 B
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UNIT-5
Sequential Circuits
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Combinational Logic
Combinational Logic:
Output depends only on current input
Has no memory
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Sequential Logic
Sequential Logic:
Output depends not only on current input but
also on past input values, e.g., design a
counter
Need some type of memory to remember the
past input values
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Sequential Circuits
Circuits that we
have learned so far
Information Storing Circuits
Timed “States”
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Sequential Logic: Concept
Sequential Logic circuits remember past
inputs and past circuit state.
Outputs from the system are
“fed back” as new inputs
With gate delay and wire delay
The storage elements are circuits that are
capable of storing binary information:
memory.
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Synchronous vs. Asynchronous
There are two types of sequential circuits:
Synchronous sequential circuit: circuit output changes only at some discrete instants of time. This type of circuits achieves synchronization by using a timing signal called the clock.
Asynchronous sequential circuit: circuit output can change at any time (clockless).
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Clock Period
F
F
F
F Combinational
Circuit
Smallest clock period = largest combinational
circuit delay between any two directly
connected FF, subjected to impact of FF
setup time.
F
F
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SR Latch (NAND version)
S’
R’
Q 1
Q’ 0
S’ R’ Q Q’ 0
1
1 0 Set
0 0 0 1 1 0 1 1
X Y NAND 0 0 1 0 1 1 1 0 1 1 1 0
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SR Latch (NAND version)
S’
R’
Q 1
Q’ 0 1
S’ R’ Q Q’ 1 0 0 0 1 1 0 Set 1 0 1 1 1 0 Hold
X Y NAND 0 0 1 0 1 1 1 0 1 1 1 0
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SR Latch (NAND version)
S’
R’
Q 0
Q’ 1 0
S’ R’ Q Q’ 1 0 0 0 1 1 0 Set 1 0 0 1 Reset 1 1 1 0 Hold
X Y NAND 0 0 1 0 1 1 1 0 1 1 1 0
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SR Latch (NAND version)
S’
R’
Q 0
Q’ 1 1
S’ R’ Q Q’ 1 0 0 0 1 1 0 Set 1 0 0 1 Reset 1 1 1 0 Hold
0 1 Hold X Y NAND 0 0 1 0 1 1 1 0 1 1 1 0
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SR Latch (NAND version)
S’
R’
Q 1
Q’ 1
S’ R’ Q Q’ 0
0
1 1 Disallowed 1 0 Set 0 1 Reset 1 0 Hold 0 1 Hold
0 0 0 1 1 0 1 1
X Y NAND 0 0 1 0 1 1 1 0 1 1 1 0
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D Latch One way to eliminate the undesirable
indeterminate state in the RS flip flop is to
ensure that inputs S and R are never 1
simultaneously. This is done in the D latch:
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D Latch with Transmission Gates
C=1 TG1 closes and TG2 opens Q’=D’ and Q=D
C=0 TG1 opens and TG2 closes Hold Q and Q’
2015/7/4 Sequential Circuits PJF - 235
1
2
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Flip-Flops
2015/7/4 Sequential Circuits PJF - 236
Latches are “transparent” (= any change
on the inputs is seen at the outputs
immediately when C=1).
This causes synchronization problems.
Solution: use latches to create flip-flops
that can respond (update) only on specific
times (instead of any time).
Types: RS flip-flop and D flip-flop
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D Flip-Flop
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Characteristic Tables
Defines the logical properties of a flip-flop
(such as a truth table does for a logic gate).
Q(t) – present state at time t
Q(t+1) – next state at time t+1
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D Flip-Flop Timing Parameters
Setup time
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Sequential Circuit Analysis
Analysis: Consists of obtaining a suitable description that demonstrates the time sequence of inputs, outputs, and states.
Logic diagram: Boolean gates, flip-flops (of any kind), and appropriate interconnections.
The logic diagram is derived from any of the following: Boolean Equations (FF-Inputs, Outputs)
State Table
State Diagram
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Example
Input:
Output:
State:
x(t)
y(t)
(A(t), B(t))
What is the Output
Function?
What is the Next State Function?
A
A C
D Q
Q
C
D Q
Q
y
x
B
CP
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Example (continued)
Boolean equations
for the functions:
A(t+1) = A(t)x(t)
+ B(t)x(t)
B(t+1) = A’(t)x(t)
y(t) = x’(t)(B(t) + A(t))
C
D Q
Q
C
D Q
Q'
y
x A
A’
B
CP
Next State
Output
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State Table Characteristics
State table – a multiple variable table with the following four sections:
Present State – the values of the state variables for each allowed state.
Input – the input combinations allowed.
Next-state – the value of the state at time (t+1) based on the present state and the input.
Output – the value of the output as a function of the present state and (sometimes) the input.
From the viewpoint of a truth table: the inputs are Input, Present State
and the outputs are Output, Next State
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State Diagrams
The sequential circuit function can be represented in graphical form as a state diagram with the following components: A circle with the state name in it for each state
A directed arc from the Present State to the Next State for each state transition
A label on each directed arc with the Input values which causes the state transition, and
A label:
On each circle with the output value produced, or
On each directed arc with the output value produced.
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Example: State Diagram
Diagram gets confusing for large circuits
For small circuit
s,
usually easier to understand than the state table
A B 0 0
0 1 1 1
1 0
x=0/y=1 x=1/y=0
x=1/y=0
x=1/y=0
x=0/y=1
x=0/y=1
x=1/y=0
x=0/y=0
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MEMORY
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Memory
Sequential circuits all depend upon the presence of memory.
A flip-flop can store one bit of information.
A register can store a single “word,” typically 32 or 64 bits.
Memory allows us to store even larger amounts of data.
Read Only Memory (ROM)
Random Access Memory (RAM)
Static RAM (SRAM)
Dynamic RAM (DRAM)
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Picture of Memory You can think of memory as being one big array of
data.
The address serves as an array index.
Each address refers to one word of data.
You can read or modify the data at any given
memory address, just like you can read or modify
the contents of an array at any given index.
Address
00000000
00000001
00000002
.
.
.
.
.
.
.
.
.
.
FFFFFFF
D
FFFFFFFE
FFFFFFFF
Data
Word
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Memory Signal Types Memory signals fall into three groups
Address bus - selects one of memory locations
Data bus
Read: the selected location’s stored data is put on the data bus
Write (RAM): The data on the data bus is stored into the selected
location
Control signals - specifies what the memory is to do
Control signals are usually active low
Most common signals are:
CS: Chip Select; must be active to do anything
OE: Output Enable; active to read data
WR: Write; active to write data
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Memory Address, Location and size
All bits in location are read/written together
Cannot manipulate single bits in a location
For k address signals, there are 2k locations in memory device
Each location contains an n bit word
Memory size is specified as
#loc x bits per location
224 x 16 RAM - 224 = 16M words, each 16 bits long
24 address lines, 16 data lines
#bits
The total storage capacity is 224 x 16 = 228 bits
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Size matters! Memory sizes are usually specified in numbers of bytes (1 byte= 8 bits).
The 228-bit memory on the previous page translates into:
228 bits / 8 bits per byte = 225 bytes
With the abbreviations below, this is equivalent to 32 megabytes.
Prefix Base 2 Base 10
K Kilo 210 = 1,024 103 = 1,000
M Mega 220 = 1,048,576 106 = 1,000,000
G Giga 230 = 1,073,741,824 109 = 1,000,000,000
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Read-only memory (ROM)
• k-bit ADRS specifies the address or location to read from
• A Chip Select, CS, enables or disables the RAM
• An Output Enable, OE, turns on or off tri-state output buffers
• Data Out will be the n-bit value stored at ADRS
2k x n ROM
ADRS Data
Out
k n
CS
OE
• Non-volatile
– If un-powered, its content retains
• Read-only
– normal operation cannot change
contents
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Programmed ROM (PROM): contents loaded at the factory
hardwired - can’t be changed
embedded mass-produced systems
OTP (One Time Programmable): Programmed by user
UVPROM: reusable, erased by UV light
EEPROM: Electrically erasable; clears entire blocks with single
operation
ROM PROGRAMMING
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ROM Usage ROMs are useful for holding data that never changes.
Arithmetic circuits might use tables to speed up computations of logarithms
or divisions.
Many computers use a ROM to store important programs that should not be
modified, such as the system BIOS.
Application programs of embedded systems,PDAs, game machines, cell
phones, vending machines, etc., are stored in ROMs
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ROM Structure
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32Kx8 ROM
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T ypical commercial EEPROMs
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Microprocessor EPROM
application
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ROM Timing
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Memories and functions ROMs are actually combinational devices, not
sequential ones!
You can store arbitrary data into a ROM, so
the same address will always contain the
same data.
You can think of a ROM as a combinational
circuit that takes an address as input, and
produces some data as the output.
A ROM table is basically just a truth table.
The table shows what data is stored at each
ROM address.
You can generate that data combinationally,
using the address as the input.
Address
A2A1A0
Data
V2V1V0
000 000
001 100
010 110
011 100 100 101
101 000
110 011
111 011
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Logic-in-ROM Example
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R eading RAM
• 50 MHz CPU – 20 ns clock cycle time
• Memory access time= 65 ns
• Maximum time from the application of the address to the
appearance of the data at the Data Output
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Enable the chip by setting CS = 1.
Select the write operation, by setting RD/WR’ = 0.
Send the desired address to the ADRS input.
Send the word to store to the DATA IN/OUT.
2k x n memory
k n ADDRESS
RD/WR’
CS
DATA
IN/OUT
WRITING RAM
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• 50 MHz CPU – 20 ns clock cycle time
• Write cycle time= 75 ns
• Maximum time from the application of the address to the
completion of all internal memory operations to store a word
WRITING RAM
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Static memory How can you implement the memory chip?
There are many different kinds of RAM.
We’ll start off discussing static memory, which is most commonly used in caches and video cards.
Later we mention a little about dynamic memory, which forms the bulk of a computer’s main memory.
Static memory is modeled using one latch for each bit of storage.
Why use latches instead of flip flops?
A latch can be made with only two NAND or two NOR gates, but a flip- flop requires at least twice that much hardware.
In general, smaller is faster, cheaper and requires less power.
The tradeoff is that getting the timing exactly right is a pain.
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RAM Cell with SR Latch
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RAM Bit Slice Model
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8x2 RAM Using a 4x4 RAM Cell
Array
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S RAM Devices
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Dynamic memory
Dynamic memory is built with capacitors.
A stored charge on the capacitor represents a logical 1.
No charge represents a logic 0.
However, capacitors lose their charge after a few milliseconds. The memory
requires constant refreshing to recharge the capacitors. (That’s what’s
“dynamic” about it.)
Dynamic RAMs tend to be physically smaller than static RAMs.
A single bit of data can be stored with just one capacitor and one
transistor, while static RAM cells typically require 4-6 transistors.
This means dynamic RAM is cheaper and denser—more bits can be
stored in the same physical area.
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DRAM Cell
• DRAM cell: One transistor and one capacitor
• 1/0 = capacitor charged/discharged
• SRAM cell: Six transistors – Costs 3 times more (cell complexity)
• Cost per bit is less for DRAM – reason for why large memories are
DRAMs
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DR AM Bit Slice
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DRAM Including Refresh
Logic